KR20200071836A - Farm Productivity Analysis System Using Big Data and Productivity Analysis Method Using It - Google Patents

Abstract

The present invention relates to a farm productivity analysis device using big data, and a productivity analysis method using the same and, more particularly, to a productivity analysis device and a productivity analysis method using the same, which collect farm data in real time through data collection units installed throughout a farm, so as to predict and analyze productivity, and predict and analyze a disease on the basis of a photograph of livestock taken through a camera installed in the farm. Therefore, productivity can be grasped through big data analysis without request of data for specialized organizations.

Description

Farm Productivity Analysis System Using Big Data and Productivity Analysis Method Using It

The present invention relates to a farm productivity and disease analysis device using big data and a productivity and disease analysis method using the same, and more specifically, predicts productivity by collecting farm data in real time by a data collection unit installed in various places on the farm. , Analyze, and predict the disease based on the pictures of livestock photographed through a camera installed on the farm. It relates to a productivity analysis device and a productivity analysis method using the same.

As crimes against agricultural products targeted to consumers increase and interest in health increases, consumers who purchase agricultural products not only check the freshness of the products, but also check the detailed information about the products to be safe and secure. You will be interested in whether the product was produced in a clean area.

In addition, producers or producers of agricultural and livestock products want to more accurately and dynamically check the agricultural and industrial data, which is data on agricultural and livestock products.

Accordingly, in general, livestock farms that raise other livestock such as chickens, ducks, pigs, dogs, cows, horses, and the like, are subject to biological changes, such as physiological changes, disease outbreaks, and emergency reversion to livestock that are raised or propagated. It is important to identify the back in a timely manner and take necessary measures.

Techniques for attaching biological devices to each of the livestock and determining the biological change of the livestock have been disclosed in Korean Patent Publication No. 10-2014-0105626 (Suncheon University Industry-Academic Cooperation Foundation, 2014.09.02., hereinafter referred to as prior art). .

The prior art has a problem in that since it is necessary to attach a biological device to each of a large number of livestock, an economic burden is applied, and since it is necessary to collect and analyze the biological change data in a batch, it is impossible to immediately identify the biological change and immediately act on it. . In addition, in order to grasp the bio-change of livestock through the bio-change data, since the bio-change data is sent to a specialized institution, and the bio-change can be grasped by receiving the analyzed data from the professional institution, there is an inefficient problem that is impossible to immediately grasp. .

Korean Open Patent No. 10-2014-0105626 (Suncheon University Industry-Academic Cooperation Foundation, 2014.09.02.)

The present invention has been devised to solve the above-mentioned problems, and a conventional user has to attach a biological device to each of the livestock, so an economic burden is applied, and the biological change or disease data must be collectively collected and analyzed. The purpose is to solve the problem that it is not possible to immediately identify and change the disease or change the body immediately.

In addition, it attempts to solve the inefficient problem, which is impossible to immediately grasp because it receives the analyzed data from a specialized institution and grasps whether there is a biological change or disease infection.

A farm server that is installed on a farm for raising livestock and analyzes productivity and disease, and stores at least one installed input unit and information on the farm, and predicts and analyzes the productivity of the farm and the disease of livestock in the farm. And a cloud server that collects, classifies, and stores information from the farm server.

The farm server is characterized in that it comprises a data collection unit for collecting data captured in the farm and images captured through the input unit and an analysis unit for analyzing and processing data collected from the data collection unit.

The analysis unit compares and analyzes an image captured through the input unit with a pre-stored picture. The data is collected in real time.

Installed in a farm for raising livestock, in a method of analyzing productivity and disease, collecting data in a farm in real time, storing data in a farm collected in real time on a farm server, and collecting farm data It is characterized in that it comprises the step of collecting and sorting in the cloud server, comparing and analyzing images or videos collected through the input unit with pre-stored photos, to grasp farm productivity or to analyze diseases.

As described above, the present invention collects data in real time and analyzes it, so that it is possible to immediately grasp the surrounding environment, to grasp an instant change in the body, and to immediately recognize whether or not a disease is infected.

In addition, it is possible to grasp productivity through big data analysis and to take immediate action against diseases, without the need to request data from specialized organizations.

1 is a view showing a big data construction according to an embodiment of the present invention.
2 is a diagram illustrating data collection according to an embodiment of the present invention.
3 is a diagram illustrating data analysis according to an embodiment of the present invention.
4 is a view showing a disease identification method according to an embodiment of the present invention.
5 is a view showing a disease identification method according to an embodiment of the present invention.

Advantages and features of embodiments of the present invention, and methods of achieving them will be apparent with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the person having the scope of the invention, and the present invention is only defined by the scope of the claims. The same reference numerals refer to the same components throughout the specification.

In describing embodiments of the present invention, when it is determined that a detailed description of known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to a user's or operator's intention or practice. Therefore, the definition should be made based on the contents throughout this specification.

The present invention relates to an apparatus and method for analyzing and predicting productivity and disease of a farm using big data, and an apparatus and method for analyzing productivity and predicting disease based on data information collected from a farm and providing it to a user will be.

Production environment, breeding environment, farm management, automation machinery, etc., which are information necessary for the entire process from birth to shipment of livestock, are collected as data information, and the collected information is converted into big data. Analyze, predict, and provide information on productivity, disease, etc., and provide productivity analysis and disease analysis results to users through varieties, breeding facilities, regions, environments, feed, and drugs through big data collected for each farm. .

The livestock described in the general specification of the present invention describes chicken as an example, but is not limited thereto, and can be applied to various livestock.

The farm productivity and disease analysis device using big data according to an embodiment of the present invention is installed on a farm for raising livestock, and is a device for analyzing productivity and disease, and is largely composed of an input unit, a farm server, and a cloud server.

At least one input unit is installed in the farm, and is provided to photograph an image of a livestock or to photograph an environment of a farm. The input unit includes not only image information in the farm, but also environment information, user input information, and the like. The use of the environment of the livestock or farm photographed by the input unit will be described later.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a big data construction according to an embodiment of the present invention. This will be described in more detail with reference to FIG. 1.

For productivity analysis and disease prediction of a farm according to an embodiment of the present invention, it is necessary to construct big data. In order to build big data, a lot of data information is required. Accordingly, it is possible to build data by connecting multiple farms to one server.

In other words, all data such as egg selection information, farm breeding information, environment information, feed bin management, water volume management, and disaster management occurring in the farm are collected in the farm server, and the farm server provided in each farm is connected to the cloud server. , Collects data from each farm server into one to predict and analyze productivity and disease.

In addition, the farm server itself is capable of analyzing productivity and predicting diseases. That is, the farm server provided in each farm collects and stores the data of each farm, and the information of each farm is stored in a cloud server and constructed as one big data. The information stored in the cloud server is provided to the user.

2 is a diagram illustrating data collection according to an embodiment of the present invention. Referring to FIG. 2, when collecting data, first, data information of a sensor, a sorter, an input unit, and a specification manager in a farm is grasped. At this time, the input unit may be a camera or the like. The information is transmitted to the data collection program of the data collector, and the date and time are input together. When the input data changes compared to previously stored data, raw data is collected, necessary data is extracted, and processing data is stored. The stored processing data is transmitted to the farm server.

At this time, if there is no change in data, the sensor, sorter, input unit, camera, and specification manager in the farm will perform monitoring again.

3 is a diagram illustrating data analysis according to an embodiment of the present invention. It will be described in more detail with reference to FIG. 3.

As illustrated in FIG. 3, a device for analyzing productivity and disease according to an embodiment of the present invention may include an input unit, a farm server, a cloud server, and a user.

The input unit includes data such as a camera, a microphone and a sensor, equipment, specifications, breeding, and production, and also includes a user input unit directly input by a user.

At this time, image and image data acquired through the input unit is image converted. The converted image is stored in a storage and classified. At this time, the criteria to be classified are classified by a behavior pattern or an image form. The converted image analyzes disease and behavior patterns.

In addition, the voice data obtained through the microphone is first, noise is removed. The voice data from which noise has been removed is also stored in the storage and classified. Based on the classified data, disease and voice patterns are analyzed.

Information input by information such as user input, sensors, devices, specifications, breeding, production, etc. is data input through clinical observation, and the data analyzes the association of diseases.

The analyzed data is stored in the farm server. All of the analyzed data is collected, and the collected data is stored in a cloud server, thereby providing information to the user.

The cloud server stores each data in various categories such as history, region, breed, feed, drug, and farm.

That is, as an example, farm A acquires data of farm A, wherein the data is obtained from an input unit, a microphone, clinical observation, a specification device, and a sensor. The input unit and the microphone are devices such as cameras, CCTVs, smart phones, and microphones installed in the farm, and the clinical observations are observation data such as mortality, culling, movement, shipping, weight, feed, drugs, drinking water, facilities, and the like. The specification device is a device such as feed measurement, negative measurement, egg screening, egg screening, and weight measuring device, and the sensor is a device for measuring temperature, humidity, carbon dioxide, ammonia, wind speed, sound pressure, intrusion detection, power failure, and the like.

Data obtained from the input unit, microphone, clinical observation, specification device, and sensor are moved to the storage and classified. The classified data is analyzed, and the data is divided into basic data, learning data, and data through learning, and based on this, disease or productivity can be predicted and disease or productivity can be analyzed.

That is, different data in the farm are analyzed by date and time, and converted data is extracted through monitoring in real time, and necessary data is transmitted to the farm server to be integrated and managed. The above data are processed through a communication protocol, a data collector for each data type, and data extracted through a data transmission program, processed as a JSON file, and transmitted to a farm server for integrated management to view information from different devices in the farm. Eliminate the inconvenience of using multiple monitoring systems and increase the accuracy of fish analysis and analysis through data integration.

That is, since the device includes a farm server and a cloud server, the farm server can collect all data such as egg selection information, farm breeding information, environmental information, feed bin management, water volume management, and disaster management occurring in the farm. Collected on the farm server, and connected to the cloud server, collects data from each farm server into one to predict and analyze productivity and disease. In addition, the farm server provided in each farm collects and stores the data of each farm, and the information of each farm is stored in a cloud server and constructed as one big data. The information stored in the cloud server is provided to the user.

That is, the cloud server includes all data and history, region, breed, feed, drug, farm, such as egg selection information, farm breeding information, environmental information, feed bin management, water volume management, disaster management, etc. Data is stored in various classifications such as stars, and the farm server provided in each farm is connected to a cloud server to analyze productivity and predict disease and data in each farm server.

In other words, it collects productivity and disease data for each farm on a cloud server, analyzes and predicts various productivity analysis, such as farm, breed, family, feed, and drug, and correlates disease to provide it to users.

In addition, it analyzes and predicts productivity according to farm productivity, for example, environment, breeding, specifications, management, etc., and provides it to users.

In addition, the farm server is characterized in that it further comprises a data collection unit for collecting data captured in the farm and images captured through the input unit and an analysis unit for analyzing and processing data collected from the data collection unit.

The data collection unit is provided to collect images and environmental information photographed from the input unit, and is provided to collect images photographed through the input unit and to collect various data such as breeding information, feed information, and volume information. . The data collection unit collects data in real time, and in this case, data collected in real time may be data such as feed amount, negative volume, humidity, and temperature, and all the collected data is stored in the farm server.

The analysis unit is provided to analyze and process the collected data. For example, it is provided to identify a disease or condition by comparing an image of a livestock photographed through the input unit with a pre-stored photograph.

In addition, installed in a farm for raising livestock, in a method of analyzing productivity and disease, a step of collecting data in a farm in real time is performed, and the size of the collected data in real time is analyzed and accumulated in a server. Then, the accumulated data is compared with pre-stored data.

4 is a view showing a disease identification method according to an embodiment of the present invention, Figure 5 is a view showing a disease identification method according to an embodiment of the present invention. 4 to 5, the disease identification method according to the embodiment will be described in more detail.

First, referring to FIG. 4, a behavioral pattern analysis and image analysis are performed on collected images or images of chicks suspected of avian encephalomyelitis. At this time, compared to the pre-stored images of live animals with avian encephalomyelitis, if a specific problem occurs, the diagnosis is made with avian encephalomyelitis, and the appropriate prescription, treatment, or treatment is performed.

That is, the image or video collected through the input unit is firstly compared and analyzed with the photo stored in the database. At this time, the database may be a database provided in a farm server or a cloud server. That is, the disease picture stored in the database and the image captured by the input unit are compared and analyzed. At this time, if avian encephalomyelitis (AE) is suspected, the chicken is clinically observed, and the production of eggs is reduced and the amount of feed intake and the amount of negative water is reduced. That is, based on the data collected on the farm, it is checked whether the chicken has a paralysis symptom, a weakened leg, a slight tremor in the head and neck, or an increased mortality. In addition, it is confirmed whether the egg production is reduced, and whether the feed intake and negative intake of the chicken are reduced. Analyze and predict the disease based on the confirmed results. Through the above confirmation, if there is no abnormality in the chicken, it is concluded that there is no specificity, and if an abnormality occurs, the user is provided with information that the chicken is suspected of avian encephalomyelitis. At this time, in providing the above information, the veterinarian is notified of the correct diagnosis, and the chicken and poultry suspected of infection are classified with the individual, and additional management is required until confirmation of diagnosis. do.

As another embodiment, referring to FIG. 5, a collected image or image of an egg having suspected avian adenovirus-egg syndrome is analyzed. Based on the collected images, the images of the eggs stored in the database are compared and analyzed. If the egg syndrome (EDS 76) is suspected, look at the collected database. In the collected database, clinical observations of chickens. Obtain clinical observation and production of eggs. Make sure that the chicken's eyesight is deteriorating and dull, diarrhea occurs, mortality increases, the egg size decreases, the eggs without shells appear, the eggs appear thin, and the color is lost. If the database shows symptoms indicating egg syndrome, it is determined as egg syndrome and informs the user that avian adenovirus-egg syndrome is suspected. At this time, the user is suspected of avian adenovirus-egg syndrome, so the veterinarian is notified of the correct diagnosis, and the suspected infection is separated from the chicken and poultry, and the confirmed infection and the poultry are removed. It also provides information, as well as information that is transmitted horizontally from other infected children.

In other words, through big data analysis such as video, audio, and clinical observation, disease prediction and analysis is performed, disease prediction and analysis are performed, and information such as location-based disease information and history-based disease information is additionally added. Informs.

The analysis unit may use artificial intelligence in comparing and analyzing the image. The analysis unit may train binary classification having 1 or 0 for the normal or abnormal egg. The binary classification has 1 or 0 as the final result, and compares the two input images to determine whether they are the same or different. That is, when an image of an egg is collected by using a binary recipe, compared with an image of an egg in a pre-stored database, a result of 1 is displayed when there is no difference, and a value of 0 is displayed when there is a difference. . At this time, the image of the egg in the pre-stored database may be an image of the diseased egg. In the above case, if a value of 1 indicating no difference appears, it can be seen that the current egg is also diseased.

In addition, based on the information in the database, a consulting unit may be further provided to assist the user in managing the farm. More specifically, farm information in the database may be provided to a consultant terminal, and consulting information received through the consultant terminal may be provided to a user terminal. The consulting proceeds with consulting on chicken or egg information made through the farm server, but is not limited thereto, and includes all consulting contents that can be provided regarding farm operation, such as a countermeasure against extreme weather. Can be.

In addition, by checking the farm information stored in the database unit, among them, by including farm information on recommendations and non-recommended cases related to the user farm as consulting information, more efficient consulting can be achieved. In addition, the consulting unit may structure and provide a common portion of consulting information received from a plurality of consultants to the user. More specifically, when the user is consulted by a plurality of consultants, by highlighting or layering a common part of the consulting information and providing it to the user, the user can more objectively recognize and use the chatting information. There will be.

In addition, the consulting unit may further include a bulletin board or a community for exchange between users or between the user and the consultant. Through this, the user can feel a sense of homogeneity and intimacy with other users and the consultant, and exchange information with each other to obtain information about each farm more effectively.

The consulting may be performed at a specific time or periodically based on the user's request through the user's terminal.

The artificial intelligence system according to an embodiment of the present invention uses an algorithm developed for a specific purpose, such as existing artificial intelligence, and big data related to the specific purpose, and is learned by a human in a laboratory or the like beforehand in the field or in practice. It is not a method to put it in, but it is possible to learn in real time while performing a task as a user next to a user who needs to be assisted (supported) by making a simple pre-learning that is possible without big data and then putting it into the field.

In the above description, various embodiments of the present invention have been presented and described, but the present invention is not necessarily limited thereto, and a person having ordinary knowledge in the technical field to which the present invention pertains may be provided without departing from the technical spirit of the present invention. It will be readily apparent that branch substitution, modification and modification are possible.

100: farm server
200: input unit
300: cloud server
400: user

Claims (5)

Installed in a farm for raising livestock, in the device for analyzing productivity and disease,
At least one input unit;
A farm server that stores farm information and predicts and analyzes productivity of the farm and diseases of livestock in the farm;
A cloud server that collects, classifies and stores information from the farm server;
Farm productivity and disease analysis apparatus using big data, characterized in that it comprises a.
The method of claim 1, wherein the farm server
A data collection unit collecting images captured through the input unit and data in a farm; And
Farm productivity and disease analysis apparatus using big data, characterized in that it comprises a; analysis unit for analyzing and processing the data collected from the data collection unit.
According to claim 1, The analysis unit
Farm productivity and disease analysis apparatus using big data, characterized in that the image captured through the input unit is compared and analyzed with a pre-stored picture.
The method of claim 1, wherein the data
Farm productivity and disease analysis device using big data, characterized in that it is collected in real time.
In the method of analyzing productivity and disease, installed on farms for raising livestock,
Collecting data in the farm in real time;
Storing the data in the farm collected in real time on the farm server;
The collected farm data is collected and classified in the cloud server;
Comparing and analyzing the image or video collected through the input unit with a pre-stored picture, grasping the productivity of the farm or analyzing the disease;
Farm productivity and disease analysis method using big data, characterized in that it comprises a.

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